Research Keyword: Mercury

Mediation and moderation by inflammation and dietary patterns in heavy metal exposure effects on kidney function

mycolabadmin

This study found that exposure to heavy metals like lead and cadmium damages kidney function by triggering inflammation in the body. Interestingly, what you eat matters significantly – a healthy diet can help protect your kidneys from heavy metal damage, while an unhealthy, pro-inflammatory diet makes the damage worse. The research suggests that eating better may be an effective way to reduce kidney disease risk from environmental pollution exposure.

Read More »

Redox-Active Metal–Organic Framework Nanocrystals for the Simultaneous Adsorption, Detection, and Detoxification of Heavy Metal Cations

mycolabadmin

This research demonstrates how specially designed metal-organic framework materials can effectively remove toxic heavy metals like mercury, lead, and cadmium from water. The most effective material, cobalt-based HHTP, can capture these metals through both chemical reactions and physical binding, making it highly efficient. The researchers also successfully coated these materials onto fabrics, creating wearable water filters that can simultaneously purify water and detect contamination levels.

Read More »

Bacterial Heavy Metal Resistance in Contaminated Soil

mycolabadmin

Heavy metals from industrial activities contaminate soil, threatening both environment and human health. Certain bacteria have evolved remarkable abilities to tolerate and neutralize these toxic metals through various mechanisms like trapping them in cell walls, pumping them out of cells, and converting them to harmless forms. By harnessing these bacterial abilities, scientists can develop sustainable and cost-effective methods to clean contaminated soils, offering hope for restoring polluted environments.

Read More »

The Strategies Microalgae Adopt to Counteract the Toxic Effect of Heavy Metals

mycolabadmin

Microalgae can help clean water polluted with toxic heavy metals like cadmium and chromium while also producing useful biomass. The review explains how microalgae absorb and trap heavy metals, and describes ways to make them more effective, including adding certain chemicals, selecting resilient strains, and using genetic modification. Combining heavy metal removal with biomass production could make the process cost-effective for real-world applications.

Read More »

Analytical Determination of Heavy Metals in Water Using Carbon-Based Materials

mycolabadmin

This review examines how special carbon-based materials can detect toxic metals like lead, cadmium, and mercury in water quickly and inexpensively. These sensors use electrochemical methods to identify metal contamination at extremely low levels, far below what could harm human health. Some newer sensors are self-powered and can show results with color changes visible to the naked eye, making them perfect for rapid testing in the field without expensive laboratory equipment.

Read More »

Bibliometric analysis of European publications between 2001 and 2016 on concentrations of selected elements in mushrooms

mycolabadmin

Researchers reviewed 200 European studies from 2001-2016 examining how mushrooms absorb heavy metals from soil. They found that mushrooms, especially edible species, can accumulate dangerous metals like cadmium, lead, and mercury, with the highest contamination in mushrooms from polluted industrial areas. Turkey, Poland, Spain, and Czech Republic led research efforts on this topic. Scientists increasingly used health risk assessment methods to determine safe consumption levels of mushrooms from different habitats.

Read More »
Scroll to Top